M. Raisch, D. Genovese, G. Fornaia, N. Zaccheroni, Simon B. Schmidt, M. L. Focarete, M. Sommer, C. Gualandi
{"title":"功能和智能材料的静电纺丝先进应用","authors":"M. Raisch, D. Genovese, G. Fornaia, N. Zaccheroni, Simon B. Schmidt, M. L. Focarete, M. Sommer, C. Gualandi","doi":"10.1063/1.5140289","DOIUrl":null,"url":null,"abstract":"The processing of advanced and functional polymers with electrospinning brings enormous potentialities to either improve or extend their properties. A representative example is the field of mechanochromic materials, potentially exploitable for imaging mechanical damages and stress/strain distribution. An effective stress-sensing material must respond to low deformation with a detectable color change that should be quickly reversible upon force unloading. In the present study we processed a spiropyran main chain polymer by electrospinning and fibers with a proper weaving were included in a PDMS elastomeric matrix to produce composite materials. Measurements of fiber birefringence demonstrated that, after electrospinning, polymer chains were successfully vitrified in a highly oriented conformation. Stress strain tests, coupled with a real-time detection of color, showed that fibers displayed a clear color change after only 5% of deformation. When these highly sensitive mechanochromic nanofibers were incorporated in a PDMS matrix, either anisotropic or isotropic mechanochromic behavior was achieved, depending on fiber alignment. The unique mechanochromic properties of the proposed composites, i.e. reversibility, sensitivity and directionality, derive by a smart combination of chemical synthesis, processing and composite design, respectively, and make them ideal to act as real-time stress/strain-sensing materials.The processing of advanced and functional polymers with electrospinning brings enormous potentialities to either improve or extend their properties. A representative example is the field of mechanochromic materials, potentially exploitable for imaging mechanical damages and stress/strain distribution. An effective stress-sensing material must respond to low deformation with a detectable color change that should be quickly reversible upon force unloading. In the present study we processed a spiropyran main chain polymer by electrospinning and fibers with a proper weaving were included in a PDMS elastomeric matrix to produce composite materials. Measurements of fiber birefringence demonstrated that, after electrospinning, polymer chains were successfully vitrified in a highly oriented conformation. Stress strain tests, coupled with a real-time detection of color, showed that fibers displayed a clear color change after only 5% of deformation. When these highly sensitive mechanochromic nanofibers were incorpo...","PeriodicalId":130539,"journal":{"name":"THE 9TH INTERNATIONAL CONFERENCE ON STRUCTURAL ANALYSIS OF ADVANCED MATERIALS - ICSAAM 2019","volume":"43 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2019-12-12","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Functional and smart materials by electrospinning for advanced applications\",\"authors\":\"M. Raisch, D. Genovese, G. Fornaia, N. Zaccheroni, Simon B. Schmidt, M. L. Focarete, M. Sommer, C. Gualandi\",\"doi\":\"10.1063/1.5140289\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The processing of advanced and functional polymers with electrospinning brings enormous potentialities to either improve or extend their properties. A representative example is the field of mechanochromic materials, potentially exploitable for imaging mechanical damages and stress/strain distribution. An effective stress-sensing material must respond to low deformation with a detectable color change that should be quickly reversible upon force unloading. In the present study we processed a spiropyran main chain polymer by electrospinning and fibers with a proper weaving were included in a PDMS elastomeric matrix to produce composite materials. Measurements of fiber birefringence demonstrated that, after electrospinning, polymer chains were successfully vitrified in a highly oriented conformation. Stress strain tests, coupled with a real-time detection of color, showed that fibers displayed a clear color change after only 5% of deformation. When these highly sensitive mechanochromic nanofibers were incorporated in a PDMS matrix, either anisotropic or isotropic mechanochromic behavior was achieved, depending on fiber alignment. The unique mechanochromic properties of the proposed composites, i.e. reversibility, sensitivity and directionality, derive by a smart combination of chemical synthesis, processing and composite design, respectively, and make them ideal to act as real-time stress/strain-sensing materials.The processing of advanced and functional polymers with electrospinning brings enormous potentialities to either improve or extend their properties. A representative example is the field of mechanochromic materials, potentially exploitable for imaging mechanical damages and stress/strain distribution. An effective stress-sensing material must respond to low deformation with a detectable color change that should be quickly reversible upon force unloading. In the present study we processed a spiropyran main chain polymer by electrospinning and fibers with a proper weaving were included in a PDMS elastomeric matrix to produce composite materials. Measurements of fiber birefringence demonstrated that, after electrospinning, polymer chains were successfully vitrified in a highly oriented conformation. Stress strain tests, coupled with a real-time detection of color, showed that fibers displayed a clear color change after only 5% of deformation. 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Functional and smart materials by electrospinning for advanced applications
The processing of advanced and functional polymers with electrospinning brings enormous potentialities to either improve or extend their properties. A representative example is the field of mechanochromic materials, potentially exploitable for imaging mechanical damages and stress/strain distribution. An effective stress-sensing material must respond to low deformation with a detectable color change that should be quickly reversible upon force unloading. In the present study we processed a spiropyran main chain polymer by electrospinning and fibers with a proper weaving were included in a PDMS elastomeric matrix to produce composite materials. Measurements of fiber birefringence demonstrated that, after electrospinning, polymer chains were successfully vitrified in a highly oriented conformation. Stress strain tests, coupled with a real-time detection of color, showed that fibers displayed a clear color change after only 5% of deformation. When these highly sensitive mechanochromic nanofibers were incorporated in a PDMS matrix, either anisotropic or isotropic mechanochromic behavior was achieved, depending on fiber alignment. The unique mechanochromic properties of the proposed composites, i.e. reversibility, sensitivity and directionality, derive by a smart combination of chemical synthesis, processing and composite design, respectively, and make them ideal to act as real-time stress/strain-sensing materials.The processing of advanced and functional polymers with electrospinning brings enormous potentialities to either improve or extend their properties. A representative example is the field of mechanochromic materials, potentially exploitable for imaging mechanical damages and stress/strain distribution. An effective stress-sensing material must respond to low deformation with a detectable color change that should be quickly reversible upon force unloading. In the present study we processed a spiropyran main chain polymer by electrospinning and fibers with a proper weaving were included in a PDMS elastomeric matrix to produce composite materials. Measurements of fiber birefringence demonstrated that, after electrospinning, polymer chains were successfully vitrified in a highly oriented conformation. Stress strain tests, coupled with a real-time detection of color, showed that fibers displayed a clear color change after only 5% of deformation. When these highly sensitive mechanochromic nanofibers were incorpo...
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